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Apache Commons BeanUtils provides an easy-to-use but flexible wrapper around reflection and introspection.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
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package org.apache.commons.beanutils2;

import java.lang.ref.Reference;
import java.lang.ref.WeakReference;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.lang.reflect.Modifier;
import java.util.Collections;
import java.util.Map;
import java.util.WeakHashMap;

import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;

/**
 * 

Utility reflection methods focused on methods in general rather than properties in particular.

* *

Known Limitations

*

Accessing Public Methods In A Default Access Superclass

*

There is an issue when invoking public methods contained in a default access superclass. * Reflection locates these methods fine and correctly assigns them as public. * However, an {@code IllegalAccessException} is thrown if the method is invoked.

* *

{@code MethodUtils} contains a workaround for this situation. * It will attempt to call {@code setAccessible} on this method. * If this call succeeds, then the method can be invoked as normal. * This call will only succeed when the application has sufficient security privileges. * If this call fails then a warning will be logged and the method may fail.

* */ public class MethodUtils { /** * Only log warning about accessibility work around once. *

* Note that this is broken when this class is deployed via a shared * classloader in a container, as the warning message will be emitted * only once, not once per webapp. However making the warning appear * once per webapp means having a map keyed by context classloader * which introduces nasty memory-leak problems. As this warning is * really optional we can ignore this problem; only one of the webapps * will get the warning in its logs but that should be good enough. */ private static boolean loggedAccessibleWarning; /** * Indicates whether methods should be cached for improved performance. *

* Note that when this class is deployed via a shared classloader in * a container, this will affect all webapps. However making this * configurable per webapp would mean having a map keyed by context classloader * which may introduce memory-leak problems. */ private static boolean CACHE_METHODS = true; /** * Stores a cache of MethodDescriptor -> Method in a WeakHashMap. *

* The keys into this map only ever exist as temporary variables within * methods of this class, and are never exposed to users of this class. * This means that the WeakHashMap is used only as a mechanism for * limiting the size of the cache, ie a way to tell the garbage collector * that the contents of the cache can be completely garbage-collected * whenever it needs the memory. Whether this is a good approach to * this problem is doubtful; something like the commons-collections * LRUMap may be more appropriate (though of course selecting an * appropriate size is an issue). *

* This static variable is safe even when this code is deployed via a * shared classloader because it is keyed via a MethodDescriptor object * which has a Class as one of its members and that member is used in * the MethodDescriptor.equals method. So two components that load the same * class via different classloaders will generate non-equal MethodDescriptor * objects and hence end up with different entries in the map. */ private static final Map> cache = Collections .synchronizedMap(new WeakHashMap>()); /** * Sets whether methods should be cached for greater performance or not, * default is {@code true}. * * @param cacheMethods {@code true} if methods should be * cached for greater performance, otherwise {@code false} * @since 1.8.0 */ public static synchronized void setCacheMethods(final boolean cacheMethods) { CACHE_METHODS = cacheMethods; if (!CACHE_METHODS) { clearCache(); } } /** * Clear the method cache. * @return the number of cached methods cleared * @since 1.8.0 */ public static synchronized int clearCache() { final int size = cache.size(); cache.clear(); return size; } /** *

Invoke a named method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@code invokeExactMethod()}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* *

This is a convenient wrapper for * {@link #invokeMethod(Object object,String methodName,Object [] args)}. *

* * @param object invoke method on this object * @param methodName get method with this name * @param arg use this argument. May be null (this will result in calling the * parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeMethod( final Object object, final String methodName, final Object arg) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { final Object[] args = toArray(arg); return invokeMethod(object, methodName, args); } /** *

Invoke a named method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@link #invokeExactMethod(Object object,String methodName,Object [] args)}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* *

This is a convenient wrapper for * {@link #invokeMethod(Object object, String methodName, Object[] args, Class[] parameterTypes)}. *

* * @param object invoke method on this object * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeMethod( final Object object, final String methodName, Object[] args) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final int arguments = args.length; final Class[] parameterTypes = new Class[arguments]; for (int i = 0; i < arguments; i++) { parameterTypes[i] = args[i].getClass(); } return invokeMethod(object, methodName, args, parameterTypes); } /** *

Invoke a named method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@link * #invokeExactMethod(Object object, String methodName, Object[] args, Class[] parameterTypes)}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* * * @param object invoke method on this object * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @param parameterTypes match these parameters - treat null as empty array * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeMethod( final Object object, final String methodName, Object[] args, Class[] parameterTypes) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (parameterTypes == null) { parameterTypes = BeanUtils.EMPTY_CLASS_ARRAY; } if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final Method method = getMatchingAccessibleMethod( object.getClass(), methodName, parameterTypes); if (method == null) { throw new NoSuchMethodException("No such accessible method: " + methodName + "() on object: " + object.getClass().getName()); } return method.invoke(object, args); } /** *

Invoke a method whose parameter type matches exactly the object * type.

* *

This is a convenient wrapper for * {@link #invokeExactMethod(Object object,String methodName,Object [] args)}. *

* * @param object invoke method on this object * @param methodName get method with this name * @param arg use this argument. May be null (this will result in calling the * parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeExactMethod( final Object object, final String methodName, final Object arg) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { final Object[] args = toArray(arg); return invokeExactMethod(object, methodName, args); } /** *

Invoke a method whose parameter types match exactly the object * types.

* *

This uses reflection to invoke the method obtained from a call to * {@code getAccessibleMethod()}.

* * @param object invoke method on this object * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeExactMethod( final Object object, final String methodName, Object[] args) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final int arguments = args.length; final Class[] parameterTypes = new Class[arguments]; for (int i = 0; i < arguments; i++) { parameterTypes[i] = args[i].getClass(); } return invokeExactMethod(object, methodName, args, parameterTypes); } /** *

Invoke a method whose parameter types match exactly the parameter * types given.

* *

This uses reflection to invoke the method obtained from a call to * {@code getAccessibleMethod()}.

* * @param object invoke method on this object * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @param parameterTypes match these parameters - treat null as empty array * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection */ public static Object invokeExactMethod( final Object object, final String methodName, Object[] args, Class[] parameterTypes) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } if (parameterTypes == null) { parameterTypes = BeanUtils.EMPTY_CLASS_ARRAY; } final Method method = getAccessibleMethod( object.getClass(), methodName, parameterTypes); if (method == null) { throw new NoSuchMethodException("No such accessible method: " + methodName + "() on object: " + object.getClass().getName()); } return method.invoke(object, args); } /** *

Invoke a static method whose parameter types match exactly the parameter * types given.

* *

This uses reflection to invoke the method obtained from a call to * {@link #getAccessibleMethod(Class, String, Class[])}.

* * @param objectClass invoke static method on this class * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @param parameterTypes match these parameters - treat null as empty array * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeExactStaticMethod( final Class objectClass, final String methodName, Object[] args, Class[] parameterTypes) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } if (parameterTypes == null) { parameterTypes = BeanUtils.EMPTY_CLASS_ARRAY; } final Method method = getAccessibleMethod( objectClass, methodName, parameterTypes); if (method == null) { throw new NoSuchMethodException("No such accessible method: " + methodName + "() on class: " + objectClass.getName()); } return method.invoke(null, args); } /** *

Invoke a named static method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@link #invokeExactMethod(Object, String, Object[], Class[])}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* *

This is a convenient wrapper for * {@link #invokeStaticMethod(Class objectClass,String methodName,Object [] args)}. *

* * @param objectClass invoke static method on this class * @param methodName get method with this name * @param arg use this argument. May be null (this will result in calling the * parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeStaticMethod( final Class objectClass, final String methodName, final Object arg) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { final Object[] args = toArray(arg); return invokeStaticMethod (objectClass, methodName, args); } /** *

Invoke a named static method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@link #invokeExactMethod(Object object,String methodName,Object [] args)}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* *

This is a convenient wrapper for * {@link #invokeStaticMethod(Class objectClass, String methodName, Object[] args, Class[] parameterTypes)}. *

* * @param objectClass invoke static method on this class * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeStaticMethod( final Class objectClass, final String methodName, Object[] args) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final int arguments = args.length; final Class[] parameterTypes = new Class[arguments]; for (int i = 0; i < arguments; i++) { parameterTypes[i] = args[i].getClass(); } return invokeStaticMethod (objectClass, methodName, args, parameterTypes); } /** *

Invoke a named static method whose parameter type matches the object type.

* *

The behavior of this method is less deterministic * than {@link * #invokeExactStaticMethod(Class objectClass, String methodName, Object[] args, Class[] parameterTypes)}. * It loops through all methods with names that match * and then executes the first it finds with compatible parameters.

* *

This method supports calls to methods taking primitive parameters * via passing in wrapping classes. So, for example, a {@code Boolean} class * would match a {@code boolean} primitive.

* * * @param objectClass invoke static method on this class * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @param parameterTypes match these parameters - treat null as empty array * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeStaticMethod( final Class objectClass, final String methodName, Object[] args, Class[] parameterTypes) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (parameterTypes == null) { parameterTypes = BeanUtils.EMPTY_CLASS_ARRAY; } if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final Method method = getMatchingAccessibleMethod( objectClass, methodName, parameterTypes); if (method == null) { throw new NoSuchMethodException("No such accessible method: " + methodName + "() on class: " + objectClass.getName()); } return method.invoke(null, args); } /** *

Invoke a static method whose parameter type matches exactly the object * type.

* *

This is a convenient wrapper for * {@link #invokeExactStaticMethod(Class objectClass,String methodName,Object [] args)}. *

* * @param objectClass invoke static method on this class * @param methodName get method with this name * @param arg use this argument. May be null (this will result in calling the * parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeExactStaticMethod( final Class objectClass, final String methodName, final Object arg) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { final Object[] args = toArray(arg); return invokeExactStaticMethod (objectClass, methodName, args); } /** *

Invoke a static method whose parameter types match exactly the object * types.

* *

This uses reflection to invoke the method obtained from a call to * {@link #getAccessibleMethod(Class, String, Class[])}.

* * @param objectClass invoke static method on this class * @param methodName get method with this name * @param args use these arguments - treat null as empty array (passing null will * result in calling the parameterless method with name {@code methodName}). * @return The value returned by the invoked method * * @throws NoSuchMethodException if there is no such accessible method * @throws InvocationTargetException wraps an exception thrown by the * method invoked * @throws IllegalAccessException if the requested method is not accessible * via reflection * @since 1.8.0 */ public static Object invokeExactStaticMethod( final Class objectClass, final String methodName, Object[] args) throws NoSuchMethodException, IllegalAccessException, InvocationTargetException { if (args == null) { args = BeanUtils.EMPTY_OBJECT_ARRAY; } final int arguments = args.length; final Class[] parameterTypes = new Class[arguments]; for (int i = 0; i < arguments; i++) { parameterTypes[i] = args[i].getClass(); } return invokeExactStaticMethod(objectClass, methodName, args, parameterTypes); } private static Object[] toArray(final Object arg) { Object[] args = null; if (arg != null) { args = new Object[] { arg }; } return args; } /** *

Return an accessible method (that is, one that can be invoked via * reflection) with given name and a single parameter. If no such method * can be found, return {@code null}. * Basically, a convenience wrapper that constructs a {@code Class} * array for you.

* * @param clazz get method from this class * @param methodName get method with this name * @param parameterType taking this type of parameter * @return The accessible method */ public static Method getAccessibleMethod( final Class clazz, final String methodName, final Class parameterType) { final Class[] parameterTypes = {parameterType}; return getAccessibleMethod(clazz, methodName, parameterTypes); } /** *

Return an accessible method (that is, one that can be invoked via * reflection) with given name and parameters. If no such method * can be found, return {@code null}. * This is just a convenient wrapper for * {@link #getAccessibleMethod(Method method)}.

* * @param clazz get method from this class * @param methodName get method with this name * @param parameterTypes with these parameters types * @return The accessible method */ public static Method getAccessibleMethod( final Class clazz, final String methodName, final Class[] parameterTypes) { try { final MethodDescriptor md = new MethodDescriptor(clazz, methodName, parameterTypes, true); // Check the cache first Method method = getCachedMethod(md); if (method != null) { return method; } method = getAccessibleMethod (clazz, clazz.getMethod(methodName, parameterTypes)); cacheMethod(md, method); return method; } catch (final NoSuchMethodException e) { return null; } } /** *

Return an accessible method (that is, one that can be invoked via * reflection) that implements the specified Method. If no such method * can be found, return {@code null}.

* * @param method The method that we wish to call * @return The accessible method */ public static Method getAccessibleMethod(final Method method) { // Make sure we have a method to check if (method == null) { return null; } return getAccessibleMethod(method.getDeclaringClass(), method); } /** *

Return an accessible method (that is, one that can be invoked via * reflection) that implements the specified Method. If no such method * can be found, return {@code null}.

* * @param clazz The class of the object * @param method The method that we wish to call * @return The accessible method * @since 1.8.0 */ public static Method getAccessibleMethod(Class clazz, Method method) { // Make sure we have a method to check if (method == null) { return null; } // If the requested method is not public we cannot call it if (!Modifier.isPublic(method.getModifiers())) { return null; } boolean sameClass = true; if (clazz == null) { clazz = method.getDeclaringClass(); } else { if (!method.getDeclaringClass().isAssignableFrom(clazz)) { throw new IllegalArgumentException(clazz.getName() + " is not assignable from " + method.getDeclaringClass().getName()); } sameClass = clazz.equals(method.getDeclaringClass()); } // If the class is public, we are done if (Modifier.isPublic(clazz.getModifiers())) { if (!sameClass && !Modifier.isPublic(method.getDeclaringClass().getModifiers())) { setMethodAccessible(method); // Default access superclass workaround } return method; } final String methodName = method.getName(); final Class[] parameterTypes = method.getParameterTypes(); // Check the implemented interfaces and subinterfaces method = getAccessibleMethodFromInterfaceNest(clazz, methodName, parameterTypes); // Check the superclass chain if (method == null) { method = getAccessibleMethodFromSuperclass(clazz, methodName, parameterTypes); } return method; } /** *

Return an accessible method (that is, one that can be invoked via * reflection) by scanning through the superclasses. If no such method * can be found, return {@code null}.

* * @param clazz Class to be checked * @param methodName Method name of the method we wish to call * @param parameterTypes The parameter type signatures */ private static Method getAccessibleMethodFromSuperclass (final Class clazz, final String methodName, final Class[] parameterTypes) { Class parentClazz = clazz.getSuperclass(); while (parentClazz != null) { if (Modifier.isPublic(parentClazz.getModifiers())) { try { return parentClazz.getMethod(methodName, parameterTypes); } catch (final NoSuchMethodException e) { return null; } } parentClazz = parentClazz.getSuperclass(); } return null; } /** *

Return an accessible method (that is, one that can be invoked via * reflection) that implements the specified method, by scanning through * all implemented interfaces and subinterfaces. If no such method * can be found, return {@code null}.

* *

There isn't any good reason why this method must be private. * It is because there doesn't seem any reason why other classes should * call this rather than the higher level methods.

* * @param clazz Parent class for the interfaces to be checked * @param methodName Method name of the method we wish to call * @param parameterTypes The parameter type signatures */ private static Method getAccessibleMethodFromInterfaceNest (Class clazz, final String methodName, final Class[] parameterTypes) { Method method = null; // Search up the superclass chain for (; clazz != null; clazz = clazz.getSuperclass()) { // Check the implemented interfaces of the parent class final Class[] interfaces = clazz.getInterfaces(); for (final Class anInterface : interfaces) { // Is this interface public? if (!Modifier.isPublic(anInterface.getModifiers())) { continue; } // Does the method exist on this interface? try { method = anInterface.getDeclaredMethod(methodName, parameterTypes); } catch (final NoSuchMethodException e) { /* Swallow, if no method is found after the loop then this * method returns null. */ } if (method != null) { return method; } // Recursively check our parent interfaces method = getAccessibleMethodFromInterfaceNest(anInterface, methodName, parameterTypes); if (method != null) { return method; } } } // We did not find anything return null; } /** *

Find an accessible method that matches the given name and has compatible parameters. * Compatible parameters mean that every method parameter is assignable from * the given parameters. * In other words, it finds a method with the given name * that will take the parameters given.

* *

This method is slightly indeterministic since it loops * through methods names and return the first matching method.

* *

This method is used by * {@link * #invokeMethod(Object object, String methodName, Object[] args, Class[] parameterTypes)}. * *

This method can match primitive parameter by passing in wrapper classes. * For example, a {@code Boolean will match a primitive boolean} * parameter. * * @param clazz find method in this class * @param methodName find method with this name * @param parameterTypes find method with compatible parameters * @return The accessible method */ public static Method getMatchingAccessibleMethod( final Class clazz, final String methodName, final Class[] parameterTypes) { // trace logging final Log log = LogFactory.getLog(MethodUtils.class); if (log.isTraceEnabled()) { log.trace("Matching name=" + methodName + " on " + clazz); } final MethodDescriptor md = new MethodDescriptor(clazz, methodName, parameterTypes, false); // see if we can find the method directly // most of the time this works and it's much faster try { // Check the cache first Method method = getCachedMethod(md); if (method != null) { return method; } method = clazz.getMethod(methodName, parameterTypes); if (log.isTraceEnabled()) { log.trace("Found straight match: " + method); log.trace("isPublic:" + Modifier.isPublic(method.getModifiers())); } setMethodAccessible(method); // Default access superclass workaround cacheMethod(md, method); return method; } catch (final NoSuchMethodException e) { /* SWALLOW */ } // search through all methods final int paramSize = parameterTypes.length; Method bestMatch = null; final Method[] methods = clazz.getMethods(); float bestMatchCost = Float.MAX_VALUE; float myCost = Float.MAX_VALUE; for (final Method method2 : methods) { if (method2.getName().equals(methodName)) { // log some trace information if (log.isTraceEnabled()) { log.trace("Found matching name:"); log.trace(method2); } // compare parameters final Class[] methodsParams = method2.getParameterTypes(); final int methodParamSize = methodsParams.length; if (methodParamSize == paramSize) { boolean match = true; for (int n = 0 ; n < methodParamSize; n++) { if (log.isTraceEnabled()) { log.trace("Param=" + parameterTypes[n].getName()); log.trace("Method=" + methodsParams[n].getName()); } if (!isAssignmentCompatible(methodsParams[n], parameterTypes[n])) { if (log.isTraceEnabled()) { log.trace(methodsParams[n] + " is not assignable from " + parameterTypes[n]); } match = false; break; } } if (match) { // get accessible version of method final Method method = getAccessibleMethod(clazz, method2); if (method != null) { if (log.isTraceEnabled()) { log.trace(method + " accessible version of " + method2); } setMethodAccessible(method); // Default access superclass workaround myCost = getTotalTransformationCost(parameterTypes,method.getParameterTypes()); if ( myCost < bestMatchCost ) { bestMatch = method; bestMatchCost = myCost; } } log.trace("Couldn't find accessible method."); } } } } if ( bestMatch != null ){ cacheMethod(md, bestMatch); } else { // didn't find a match log.trace("No match found."); } return bestMatch; } /** * Try to make the method accessible * @param method The source arguments */ private static void setMethodAccessible(final Method method) { try { // // XXX Default access superclass workaround // // When a public class has a default access superclass // with public methods, these methods are accessible. // Calling them from compiled code works fine. // // Unfortunately, using reflection to invoke these methods // seems to (wrongly) to prevent access even when the method // modifier is public. // // The following workaround solves the problem but will only // work from sufficiently privileges code. // // Better workarounds would be gratefully accepted. // if (!method.isAccessible()) { method.setAccessible(true); } } catch (final SecurityException se) { // log but continue just in case the method.invoke works anyway final Log log = LogFactory.getLog(MethodUtils.class); if (!loggedAccessibleWarning) { boolean vulnerableJVM = false; try { final String specVersion = System.getProperty("java.specification.version"); if (specVersion.charAt(0) == '1' && (specVersion.charAt(2) == '0' || specVersion.charAt(2) == '1' || specVersion.charAt(2) == '2' || specVersion.charAt(2) == '3')) { vulnerableJVM = true; } } catch (final SecurityException e) { // don't know - so display warning vulnerableJVM = true; } if (vulnerableJVM) { log.warn( "Current Security Manager restricts use of workarounds for reflection bugs " + " in pre-1.4 JVMs."); } loggedAccessibleWarning = true; } log.debug("Cannot setAccessible on method. Therefore cannot use jvm access bug workaround.", se); } } /** * Returns the sum of the object transformation cost for each class in the source * argument list. * @param srcArgs The source arguments * @param destArgs The destination arguments * @return The total transformation cost */ private static float getTotalTransformationCost(final Class[] srcArgs, final Class[] destArgs) { float totalCost = 0.0f; for (int i = 0; i < srcArgs.length; i++) { Class srcClass, destClass; srcClass = srcArgs[i]; destClass = destArgs[i]; totalCost += getObjectTransformationCost(srcClass, destClass); } return totalCost; } /** * Gets the number of steps required needed to turn the source class into the * destination class. This represents the number of steps in the object hierarchy * graph. * @param srcClass The source class * @param destClass The destination class * @return The cost of transforming an object */ private static float getObjectTransformationCost(Class srcClass, final Class destClass) { float cost = 0.0f; while (srcClass != null && !destClass.equals(srcClass)) { if (destClass.isPrimitive()) { final Class destClassWrapperClazz = getPrimitiveWrapper(destClass); if (destClassWrapperClazz != null && destClassWrapperClazz.equals(srcClass)) { cost += 0.25f; break; } } if (destClass.isInterface() && isAssignmentCompatible(destClass,srcClass)) { // slight penalty for interface match. // we still want an exact match to override an interface match, but // an interface match should override anything where we have to get a // superclass. cost += 0.25f; break; } cost++; srcClass = srcClass.getSuperclass(); } /* * If the destination class is null, we've traveled all the way up to * an Object match. We'll penalize this by adding 1.5 to the cost. */ if (srcClass == null) { cost += 1.5f; } return cost; } /** *

Determine whether a type can be used as a parameter in a method invocation. * This method handles primitive conversions correctly.

* *

In order words, it will match a {@code Boolean to a boolean}, * a {@code Long to a long}, * a {@code Float to a float}, * a {@code Integer to a int}, * and a {@code Double to a double}. * Now logic widening matches are allowed. * For example, a {@code Long will not match a int}. * * @param parameterType the type of parameter accepted by the method * @param parameterization the type of parameter being tested * * @return true if the assignment is compatible. */ public static final boolean isAssignmentCompatible(final Class parameterType, final Class parameterization) { // try plain assignment if (parameterType.isAssignableFrom(parameterization)) { return true; } if (parameterType.isPrimitive()) { // this method does *not* do widening - you must specify exactly // is this the right behavior? final Class parameterWrapperClazz = getPrimitiveWrapper(parameterType); if (parameterWrapperClazz != null) { return parameterWrapperClazz.equals(parameterization); } } return false; } /** * Gets the wrapper object class for the given primitive type class. * For example, passing {@code boolean.class returns Boolean.class} * @param primitiveType the primitive type class for which a match is to be found * @return the wrapper type associated with the given primitive * or null if no match is found */ public static Class getPrimitiveWrapper(final Class primitiveType) { // does anyone know a better strategy than comparing names? if (boolean.class.equals(primitiveType)) { return Boolean.class; } else if (float.class.equals(primitiveType)) { return Float.class; } else if (long.class.equals(primitiveType)) { return Long.class; } else if (int.class.equals(primitiveType)) { return Integer.class; } else if (short.class.equals(primitiveType)) { return Short.class; } else if (byte.class.equals(primitiveType)) { return Byte.class; } else if (double.class.equals(primitiveType)) { return Double.class; } else if (char.class.equals(primitiveType)) { return Character.class; } else { return null; } } /** * Gets the class for the primitive type corresponding to the primitive wrapper class given. * For example, an instance of {@code Boolean.class returns a boolean.class}. * @param wrapperType the * @return the primitive type class corresponding to the given wrapper class, * null if no match is found */ public static Class getPrimitiveType(final Class wrapperType) { // does anyone know a better strategy than comparing names? if (Boolean.class.equals(wrapperType)) { return boolean.class; } else if (Float.class.equals(wrapperType)) { return float.class; } else if (Long.class.equals(wrapperType)) { return long.class; } else if (Integer.class.equals(wrapperType)) { return int.class; } else if (Short.class.equals(wrapperType)) { return short.class; } else if (Byte.class.equals(wrapperType)) { return byte.class; } else if (Double.class.equals(wrapperType)) { return double.class; } else if (Character.class.equals(wrapperType)) { return char.class; } else { final Log log = LogFactory.getLog(MethodUtils.class); if (log.isDebugEnabled()) { log.debug("Not a known primitive wrapper class: " + wrapperType); } return null; } } /** * Find a non primitive representation for given primitive class. * * @param clazz the class to find a representation for, not null * @return the original class if it not a primitive. Otherwise the wrapper class. Not null */ public static Class toNonPrimitiveClass(final Class clazz) { if (clazz.isPrimitive()) { final Class primitiveClazz = MethodUtils.getPrimitiveWrapper(clazz); // the above method returns if (primitiveClazz != null) { return primitiveClazz; } } return clazz; } /** * Gets the method from the cache, if present. * * @param md The method descriptor * @return The cached method */ private static Method getCachedMethod(final MethodDescriptor md) { if (CACHE_METHODS) { final Reference methodRef = cache.get(md); if (methodRef != null) { return methodRef.get(); } } return null; } /** * Add a method to the cache. * * @param md The method descriptor * @param method The method to cache */ private static void cacheMethod(final MethodDescriptor md, final Method method) { if (CACHE_METHODS && method != null) { cache.put(md, new WeakReference<>(method)); } } /** * Represents the key to looking up a Method by reflection. */ private static class MethodDescriptor { private final Class cls; private final String methodName; private final Class[] paramTypes; private final boolean exact; private final int hashCode; /** * The sole constructor. * * @param cls the class to reflect, must not be null * @param methodName the method name to obtain * @param paramTypes the array of classes representing the parameter types * @param exact whether the match has to be exact. */ public MethodDescriptor(final Class cls, final String methodName, Class[] paramTypes, final boolean exact) { if (cls == null) { throw new IllegalArgumentException("Class cannot be null"); } if (methodName == null) { throw new IllegalArgumentException("Method Name cannot be null"); } if (paramTypes == null) { paramTypes = BeanUtils.EMPTY_CLASS_ARRAY; } this.cls = cls; this.methodName = methodName; this.paramTypes = paramTypes; this.exact= exact; this.hashCode = methodName.length(); } /** * Checks for equality. * @param obj object to be tested for equality * @return true, if the object describes the same Method. */ @Override public boolean equals(final Object obj) { if (!(obj instanceof MethodDescriptor)) { return false; } final MethodDescriptor md = (MethodDescriptor)obj; return exact == md.exact && methodName.equals(md.methodName) && cls.equals(md.cls) && java.util.Arrays.equals(paramTypes, md.paramTypes); } /** * Returns the string length of method name. I.e. if the * hashcodes are different, the objects are different. If the * hashcodes are the same, need to use the equals method to * determine equality. * @return the string length of method name. */ @Override public int hashCode() { return hashCode; } } }





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